Influence de charges carbonées sur la dissipation thermique de nouveaux composites diélectriques / Influence of carbon fillers on the heat dissipation of new dielectric composites

Diaz Chacon, Lurayni

09 December 2016

La plupart des équipements électroniques et électriques sont enrobés ou encapsulés par de la résine epoxy, choisie pour ses qualités physiques, chimiques et surtout diélectriques. Cependant, ce matériau présente un inconvénient majeur : sa faible conductivité thermique (0.2 W/mK). Dans ce contexte, nous avons élaboré et caractérisé des composites epoxy / carbone dans le but d’améliorer la conductivité thermique de ce type de résine tout en conservant ses propriétés diélectriques. Nous avons ainsi testé le potentiel d’une large gamme de charges carbonées, de structures, formes et tailles variées (sphères, tubes et plaquettes), telles que des micro-sphères de carbone et des nanotubes multi-parois synthétisées par CVD et PECVD, mais aussi des charges industrielles : nano-plaquettes de graphite (graphite exfolié), du coke de pétrole, du graphite synthétique et naturel. Des échantillons de matériaux composites massifs (50 x 50 x 4 mm) ont été préparés à partir d’une résine industrielle DGEBA de viscosité élevée 8.5-15 Pa.s, en faisant varier le taux de charge. Les propriétés thermiques des composites ont été mesurées à partir de la technique du hot disk (source plane instationnaire). Les meilleurs résultats ont été obtenus à partir des nano-plaquettes de graphite : les conductivités thermiques des composites ont atteint (0.55 W/mK) pour une charge admissible maximale de 2.67 vol.%. L’accroissement relatif de conductivité thermique a été de 66 % pour 1 vol.%. Cet accroissement est particulièrement élevé dans la mesure où les meilleurs résultats reportés sont de 20 % / vol.% dans le cas de résines à viscosité plus faible de type DGEBF (2.5 - 4.5 Pa.s). La concentration de charge admissible (1.3 vol.%) pour conserver une résistivité électrique suffisamment élevée (> 105 ohm.m) nous a permis d’atteindre une conductivité thermique de 0.37 W/mK (soit une augmentation de 100% par rapport à la résine initiale). Ces résultats sont interprétés en termes de transport des phonons acoustiques dans un système composite bi-phasique. Les nano-plaquettes de graphite sont caractérisées par une morpholigie anisotrope, d’ une surface d’environ 26 x 26 microns dont l’épaisseur est de l’ordre de 6 nm. Elles combinent une structure lamellaire périodique bien ordonnée dans les plans de graphène (caractérisation par XPS, EDX et DRX), et des rapports d’acicularité élevés ( 4300), estimés à partir de différentes techniques : TEM, SEM et BET. Nous montrons qu’accroitre l’acicularité des nano-plaquettes de graphite par exfoliation, en préservant une grande surface des plans de graphène, et sans générer de défauts de structure, constitue un défi. Cette morphologie 2D particulière permet d’une part de conserver voire augmenter la conductivité intrinsèque des charges, favorisée dans les plans de graphène, et d’autre part, en raison de leur grande surface spécifique, de garantir après leur dispersion dans la résine, un meilleur transport des phonons acoustiques dans le composite. / Most electronic and electrical equipment are coated or encapsulated by epoxy resin due to its physical, chemical and dielectric properties. However, this material has a major drawback: its low thermal conductivity ( 0.2 W / mK). In this context, we have developed and characterized epoxy / carbon composites in order to improve the thermal conductivity of this type of resin while maintaining its dielectric properties. We have tested the potential of a wide range of carbonaceous fillers, structures, shapes and sizes (spheres, tubes and plates), such as carbon micro-spheres and multi-walled carbon nanotubes synthesized by CVD and PECVD, but also industrial fillers: graphite nano-platelets (exfoliated graphite), petroleum coke, synthetic and natural graphite. Large composite samples (50 x 50 x 4 mm) were prepared from a DGEBA engineering resin of high viscosity 8.5-15 Pa.s, by varying the charge vol%. The thermal properties of the composites were measured from the transient plane source technique (hot disk). The best results are obtained from graphite nano-platelets: the thermal conductivity reach (0.55 W / mK) for a maximum load of 2.67 vol%.. The relative increase of thermal conductivity is 66% to 1 vol.%. This increase is particularly high to the extent that the best results reported so far is 20% / vol% for resins with lower viscosity, type DGEBF (2.5 - 4.5 Pa.s). The allowable concentration (1.3 vol.%) to maintain a sufficiently high electrical resistivity (> 105 ohm.m) permits to increase of the thermal conductivity to 100% (0.37 W / mK) compared to the initial resin. These results are interpreted in terms of transport of acoustic phonons in the composite two-phase system. Graphite nano-platelets are characterized by anisotropic shapes with a surface of about 26 x 26 microns whose thickness is of the order of 6 nm. They combine an ordered periodic structure in graphene planes (characterization by XPS, EDX and XRD), and a high aspect ratio ( 4300), estimated using various techniques: TEM, SEM and BET. We show that graphite exfoliation permit to increase the aspect ratio of graphite nanoplatelets, maintaining large micronic graphene surface, and without generating structural defects is a challenge. This peculiar 2D morphology allows on one hand, to retain or even increase the intrinsic filler conductivity, favored in the graphene planes, and on another hand, due to their high surface area, to ensure after their dispersion in the resin, a better transport of acoustic phonons through the composite.

Composites epoxy-Carbone

Nanostructures carbonées

Conductivité thermique

Graphite exfolié

Composites diélectriques

Epoxy-Carbon composits

Carbon nanostructures

Thermal conductivity

Exfoliated graphite

Dielectric composites

ADSORÇÃO DE INTERFERENTES ENDÓCRINOS EM GRAFENO E DERIVADOS: AVALIAÇÃO TEÓRICA E EXPERIMENTAL

Jauris, Iuri Medeiros

21 November 2016

Submitted by MARCIA ROVADOSCHI (marciar@unifra.br) on 2018-08-20T12:17:09Z No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) Tese_IuriMedeirosJauris.pdf: 8625676 bytes, checksum: 6980ea50a786db7523d0559ac05b09bb (MD5) / Made available in DSpace on 2018-08-20T12:17:09Z (GMT). No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) Tese_IuriMedeirosJauris.pdf: 8625676 bytes, checksum: 6980ea50a786db7523d0559ac05b09bb (MD5) Previous issue date: 2016-11-21 / Various chemical pollutants and substances named endocrine disruptors compounds (EDCs) has become commonly detected in wastewater and even in drinking water in many countries. In contrast the adsorption technique has been considered by many researcher as a promising method to treatment and purification of wastewater, mainly due to its ease of operation, high efficiency and low cost. Meanwhile, carbon nanomaterials such as nanotubes, and graphene, have been reported in the literature as promising materials to adsorb and removing various types of contaminants from wastewater. From this perspective, the main goal of this study was the evaluation of the use of graphene, functionalized graphene and reduced graphene oxide (rGO), in the adsorption and removal of drugs in aqueous medium. The removal efficiency was measured using diclofenac sodium (DCL) and nimesulide (NIME) in aqueous solutions and analizing sorption equilibrium conditions as well as kinetics and adsorption isotherms in the rGO. At the same time, through ab initio calculations, computational simulations were carried out to better understand how the structural and electronic characteristics of the adsorbent material can influence the adsorption process. Thus, through the batch experiments, it was found that the rGO showed a good ability to successfully remove NIME and DCL drugs from aqueous solutions. The maximum percentage removal of DCL by rGO was 80.4% and 79.3% for the initial concentrations of 40 and 70 mg.L-1, respectively. The maximum sorption capacity for adsorption of the DCL drug at 25ºC was 59.67 mg.g-1. The maximum percentage removal of NIME by rGO was 92.2% and 82.9% for the initial concentrations of 40 and 70 mg.L-1, respectively. The thermogravimetric and FTIR spectroscopy analyzes revealed that DCL and NIME was successfully adsorbed by rGO. In addition, theoretical results showed that the interaction between DCL and NIME with pristine or functionalized graphene, occurs by physical adsorption, being maintained mainly due to π-π interactions and hydrogen bonding. The results provide valuable information for better understanding the behavior of physicochemical properties in the evaluated interactions. Based on these results, the ab initio calculations and the adsorption experiments point out that the graphene and functionalized graphene or rGO are promising materials for extracting DCL and NIME drugs from wastewater effluents. / A detecção de poluentes químicos diversos e substâncias conhecidas com interferentes endócrinos (IEs) em águas residuais e até mesmo na água potável, tem se tornado cada vez mais frequente em inúmeros países. Em contrapartida a técnica de adsorção, tem sido considerado por muitos pesquisadores como um método promissor de tratamento e purificação da água proveniente de efluentes, devido, principalmente, a sua facilidade de operação, alta eficiência e baixo custo. Paralelamente, os nanomateriais de carbono, tais como nanotubos e o grafeno vêm sendo reportados na literatura como materiais de grande capacidade para adsorção e remoção de diversos tipos de produtos químicos de águas residuais. Nesse sentido, o foco desse estudo foi a avaliação do uso do grafeno, grafeno funcionalizado e óxido de grafeno reduzido (rGO), na adsorção e remoção de fármacos em meio aquoso. A avaliaçao da eficiência de remoção foi conduzida empregando-se diclofenaco sódico (DCL) e a nimesulida (NIME) em soluções aquosas e avaliando-se as condições de equilíbrio de sorção e também cinética e isotermas de adsorção no rGO. Paralelamente, através de cálculos de primeiros princípios, foram realizadas simulações computacionais para melhor compreensão de como as características estruturais e eletrônicas do material adsorvente, podem influenciar no processo adsortivo. Assim, através dos experimentos em batelada, observou-se um percentual de remoção máximo do DCL pelo rGO de 80,4% e 79,3% para as concentrações iniciais de 40 e 70 mg.L-1. A capacidade máxima encontrada de adsorção do DCL pelo rGO a 25ºC foi de 59,67mg.g-1. O percentual de remoção máximo da NIME pelo rGO foi 92,2 % e 82,9% para as concentrações iniciais de 40 e 70 mg.L-1 . O pH foi fixo em 10,0 para todos os experimentos. As análises termogravimétricas para adsorção do DCL e NIME em rGO, e de espectroscopia FTIR para adsorção da NIME em rGO, revelaram que os fármacos foram adsorvidos com sucesso pelo rGO. Em adição os resultados teóricos mostraram que a interação do DCL e da NIME com o grafeno puro e os grafenos funcionalizados ocorreram através da adsorção física, sendo essa mantida em grande parte devido às interações do tipo π-π e ligações de hidrogênio. Os resultados obtidos fornecem subsídios para a melhor compreensão do comportamento das propriedades físico-químicas nas interações avaliadas. Baseado nesses resultados, os cálculos de primeiros princípios e os experimentos de adsorção revelaram que o grafeno puro, grafeno funcionalizado, ou rGO, são materiais promissores para remoção dos fármacos DCL e NIME de soluções aquosas.

Biociências e Nanomateriais

Synthesis Of Various Carbon Nanostructures And The Transport Properties Of Carbon Nanotubes

Singh, Laishram Tomba

11 1900

Different carbon nanostructures have different properties and different applications. It is needed to synthesize good quality and also on large scale. From the point of industrial applications, highly productive and low cost synthesis method is very essential. Research has been done extensively on the intrinsic and individual properties of both single walled carbon nanotubes (SWCNTs) and multiwalled carbon nanotubes (MWC-NTs) in the range of nanometer to micrometer length scale. The important question is how the properties change beyond this length scale and if they are used in group in the form of an array instead of the individual carbon nanotubes (CNTs). Some applications require large current output, large energy production etc. For such kind of applications, it becomes essential to use CNTs in large number in the form of arrays or array, instead of using large numbers of CNTs in individual level. Future nanotechnology scope requires large scale application using the very rich intrinsic properties of the CNTs and nanomaterials. Keeping these problems and challenges in front, this thesis work is devoted to the research of the large scale synthesis of mm long MWCNTs, having different morphology and studies on various physical properties of MWCNTs in the form of arrays. Synthesis of mm long aligned and buckled MWCNTs have been reported for the first time. Generally buckled CNTs were obtained by compressing the straight CNTs. Apart from this, different morphologies like, aligned straight, helical or coiled CNTs are also synthesized. Resistance of the individual CNT increases with the increase in length. Resistance versus length of an array of CNT also shows similar behaviour. The thermal conductivity of CNT array is observed to decrease with the increase of array diameter (diameter �100 µm). There are few reports of the similar behaviour with the experiments done on small diameter CNT arrays (diameter �100 nm). From these observations, it seems that in the arrays of CNT, their intrinsic individual property is preserved though the magnitudes are different. The conductance measurements done on buckled CNT array by compressing it to apply uniaxial strain, shows the conductance oscillation. This conductance oscillation seems to be originating from the band gap change due to strain when the CNTs bend during compression. Recent research focuses on the arrays of CNT as they can carry large current of the order of several milliamperes that make the arrays suitable in nanoscale electronics and in controlling macroscopic devices such as light emitting diodes and electromotors. Regarding this aspect, a part of this thesis work is devoted on the application of CNT array to field effect transistor (FET) and study of thermoelectric power generation using CNT arrays. The entire thesis is based on the works discussed above. It has been organized as follows: Chapter 1 deals with introduction about the different carbon nanostructures and different synthesis methods. A brief introduction about the different current-voltage (IV) characteristics of SWCNTs and MWCNTs, length and diameter dependence and effect of the mode of contacts, are given. Some applications of the array of CNTs like buckling effect on compression, stretching of CNT into the form of rope, and conduction change on compression are discussed. Application of CNT as FET, as a thermometer, and thermoelectric effect of CNT are discussed. The electromechanical effect of CNT is also discussed briefly. Chapter 2 deals with experimental setup for synthesis of different morphologies of carbon nanostructures. The samples are characterized using common characterization techniques like, scanning electron microscopy (SEM), transmission electron microscopy (TEM) and Raman spectroscopy. A brief introduction about Raman Spectroscopy of CNT is given. Chapter 3 reports the unusual IV characteristics and breakdown of long CNT arrays. The current carrying ability and the threshold voltage as a function of array diameter are reported. The effect of the ambient like temperature and pressure are discussed. Chapter 4 deals with theoretical models to analyze the IV characteristics reported in Chapter 3. It has been shown that a set of classical equations are applicable to quantum structures and the band gap can be evaluated. Chapter 5 describes with application of CNT arrays as temperature sensors. It has been shown that CNT arrays of suitable diameters are used as temperature sensors after calibration. Chapter 6 reports the high current FET application of CNT arrays. Effects of temperature and ambient pressure are discussed. The type of the majority charge carrier is determined. Chapter 7 deals with application of CNT arrays as thermoelectric power generator to get large thermoelectric current. Effects of different array diameter are discussed. Modulation of thermoemf with gate voltage is discussed. The type of the majority charge carrier is determined. Chapter 8 reports the effect of compressive strain on buckled MWCNT arrays. Conductance is measured during the compression of the array. Quantum electromechanical conductance oscillation is observed. The structural changes are observed with SEM. Raman spectroscopic study supports the explanation of the effect. Chapter 9 provides the conclusion and overall summary of the thesis.

Carbon Nanotube (CNT)

Nano Technology

Transport Properties

Single-walled Carbon Nanotube (SWCNT)

Multiwalled Carbon Naotube (MWCNT)

Multiwalled Carbon Nanotube Arrays

Carbon Nanotube Arrays

Carbon Nanostructures

Nanotechnology

Nanoestruturas de carbono para o armazenamento de hidrogênio : estudos computacionais / Carbon nanostructures for hydrogen storage : computational studies

Faro, Tatiana Mello da Costa, 1987-

26 August 2018

Orientadores: Munir Salomão Skaf, Vitor Rafael Coluci / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-26T20:42:42Z (GMT). No. of bitstreams: 1 Faro_TatianaMellodaCosta_D.pdf: 8054394 bytes, checksum: ce0d79df42ce453ffc39b51bf0ad1094 (MD5) Previous issue date: 2015 / Resumo: Atualmente, a economia mundial depende do uso de combustíveis fósseis para a geração de energia. Esse modelo apresenta problemas ambientais graves, uma vez que o petróleo é um material não-renovável e muito poluente. O gás hidrogênio apresenta-se como uma alternativa promissora para substituir os combustíveis utilizados atualmente devido a um conjunto de características positivas: ele é atóxico, tem uma alta densidade energética gravimétrica e gera apenas água como produto de sua combustão. Apesar de tais vantagens, ele ainda não é utilizado comercialmente em larga escala. O maior empecilho tecnológico para que o hidrogênio possa substituir os combustíveis fósseis está no seu armazenamento. Existem diversas propostas para armazenar o hidrogênio, como tanques contendo o hidrogênio nas formas de gás pressurizado ou de líquido, além de sistemas sólidos que permitam a sua adsorção. Todavia, nenhum sistema construído até então foi capaz de armazenar o hidrogênio de forma tão barata, segura e eficaz quanto seria necessário. Nanoestruturas de carbono são vistas como uma boa alternativa para construir dispositivos de armazenamento de hidrogênio baseados na fisissorção. Os nanopapiros de carbono, formados por folhas de grafeno enroladas no formato de um papiro, são considerados particularmente promissores para armazenar o hidrogênio, uma vez que possuem uma alta área superficial, extremidades abertas e distâncias intercamadas facilmente controláveis. Na primeira etapa deste trabalho, realizamos simulações de Dinâmica Molecular (MD) para estudar a dinâmica e a estabilidade de diversos nanopapiros em função de alguns dos seus parâmetros estruturais. Posteriormente, aplicamos o método de Monte Carlo Grand-Canônico (GCMC) para estudar o processo de adsorção de hidrogênio em nanopapiros selecionados, de forma a caracterizar quantitativamente e qualitativamente as fases adsorvidas / Abstract: Presently, the world economy depends on the use of fossil fuels to generate energy. This model presents serious environmental problems, since petroleum is a non-renewable and very pollutant material. Hydrogen gas presents itself as a promising alternative to substitute the fuels currently used due to a few positive characteristics: it is non-toxic, possesses a high gravimetric energetic density and only generates water as a combustion byproduct. In spite of all these advantages, hydrogen still isn't used commercially in a large scale. The biggest technological drawback for hydrogen to substitute fossil fuels is in its storage. There are many proposed ways to store hydrogen, such as tanks containing highly pressurized or liquid hydrogen, or solid systems that allow its adsorption. However, no system built up to the date had been able to store hydrogen as cheap, safe and efficiently as necessary. Carbon nanostructures are seen as a good alternative to build hydrogen storage devices based on physisorption. Carbon nanoscrolls, formed by graphene sheets scrolled in a papirus-like shape, are considered as particularly promising adsorption materials, since they possess a high surface area, open edges and easily controllable interlayer distances. In the first step of this work, we made Molecular Dynamics (MD) simulations to study the dynamics and the stability of several nanoscrolls as a function of their structural parameters. Subsequently, we used the Grand-Canonical Monte Carlo (GCMC) method to study the hydrogen adsorption process in selected nanoscrolls, as to characterize the adsorbed phases quantitatively and qualitatively / Doutorado / Físico-Química / Doutora em Ciências

Dinâmica molecular

Monte Carlo Grand-Canônico

Nanoestruturas de carbono

Nanopapiros de carbono

Hidrogenio - Armazenamento

Molecular dynamics

Grand-canonical Monte Carlo

Carbon nanostructures

Carbon nanoscrolls

Hydrogen - Storage

Herstellung und Charakterisierung von irregulären Kohlenstoff-Nanostrukturen

Hentsche, Melanie

18 December 2006

Die vorliegende Promotion beinhaltet die Untersuchung von irregulären Kohlenstoff-Nanostrukturen, die mittels Hochenergie-Kugelmahlen hergestellt wurden. Die wissenschaftliche Herausforderung besteht darin, die strukturelle Vielfalt dieser Nanostrukturen experimentell zu erfassen, zu klassifizieren und bezüglich ausgewählter Eigenschaften zu bewerten, sowie mit den Herstellungsparametern in Zusammenhang zu bringen. Die Pulver konnten nach den Mahlungen hinsichtlich ihrer Struktur in zwei grundsätzliche Typen eingeteilt werden: (I) ein Nanopulver, das aus graphitischen Stapelpaketen besteht, welche in eine amorphe Matrix eingebettet sind, (II) ein vollständig amorphisiertes Pulver. Die Strukturanalyse in Bezug auf die Mahlbedingungen (Mahlatmosphäre, Mahltemperatur) zeigt, dass die Dauer der Nanostrukturierung sowie die Anzahl und Größe von graphitischen Stapelpaketen gezielt beeinflusst werden kann. Außerdem konnten Hinweise gefunden werden, die darauf hindeuten, dass Mahlen bei tiefen Temperaturen oder unter Wasserstoffatmosphäre die Agglomeration der Nanopartikel verringern kann. Das Kugelmahlen ermöglicht es ebenfalls, die spezifische Oberfläche des Graphitpulvers von 5,5 m2/g auf 725 m2/g innerhalb von fünf Mahlstunden zu erhöhen. Der Anteil der Verunreinigungen (Fe) liegt dabei nicht höher als 0,05 wt%. Es ist jedoch zu beachten, dass sämtliche Eigenschaften stark von den verschiedenen Mahlparametern (Mahltemperatur, Mahlmaterial) abhängen. Die für Adsorptionsuntersuchungen optimalen Eigenschaften (große spezifische Oberfläche, erhöhte Reaktivität, geringe Verunreinigungen) werden schon nach kurzer Mahldauer erreicht. Wiederholungsmahlungen und Wiederholungsmessungen verschiedener Eigenschaften (spezifische Oberfläche, Verbrennungstemperatur) machen deutlich, dass die Ergebnisse reproduzierbar sind, und dass keine Alterungserscheinungen während der Lagerung unter Argonatmosphäre im Zeitraum von einem Jahr auftreten. Die Wasserstoffspeicherung an nanostrukturierten Kohlenstoffpulvern konnte nachgewiesen werden. Die maximalen Speicherkapazitäten für Temperaturen nahe 77 K lagen bei 1,5 wt%. Für niedrigere Temperaturen Tist = 35 K zeigten sich höhere Speicherkapazitäten von bis zu 5 wt%. Die Korrelation der ermittelten Speicherkapazitäten mit den theoretisch erreichbaren Werten in Bezug auf die Oberfläche der Proben zeigt, dass im Experiment deutlich höhere Werte erhalten werden. Dies lässt den Schluss zu, dass neben der Speicherung an der Oberfläche der Pulver ein weiterer Speichermechanismus innerhalb der Mikroporen der Proben stattfindet.

info:eu-repo/classification/ddc/620

ddc:620

Plasma based assembly and engineering of advanced carbon nanostructures / Plasmas appliqués à la production de nanostructures de carbone avancées

Vieitas de Amaral Dias, Ana Inês

04 October 2018

L’environnement réactif du plasma constitue un outil puissant dans la science des matériaux, permettant la création de matériaux innovatifs et l'amélioration de matériaux existants qui ne serait autrement pas possible.Le plasma fournit simultanément des fluxes de particules chargées, des molécules chimiquement actives, des radicaux, de la chaleur, des photons, qui peuvent fortement influencer les voies d'assemblage à différentes échelles temporelles et spatiales, y compris à l’échelle atomique.Dans cette thèse de doctorat, des méthodes tenant pour base des plasmas micro-ondes ont été utilisées pour la synthèse de nanomatériaux de carbone, y compris graphène, graphène dopé à l'azote (N-graphène) et structures de type diamant.À cette fin, ce travail est lié à optimisation de la synthèse de nanostructures 2D du carbone, comme graphène et N-graphène par la poursuite de l'élaboration et du raffinement de la méthode développée en Plasma Engineering Laboratory (PEL). La synthèse de graphène de haute qualité et en grandes quantités a été accomplie avec succès en utilisant des plasmas d'Ar-éthanol à ondes de surface dans des conditions de pression ambiante. De plus, le N-graphène a été synthétisé par un procédé en une seule étape, de l'azote a été ajouté au mélange d’Ar-éthanol, et par un procédé en deux étapes, en soumettant des feuilles de graphène préalablement synthétisées ont été exposées à un traitement plasma argon-azote à basse pression. Les atomes d'azote ont été incorporés avec succès dans le réseau de graphène hexagonal, formant principalement liaisons pyrroliques, pyridiniques et quaternaires. Un niveau de dopage de 25 at.% a été atteint.Différents types de nanostructures de carbone, y compris du graphène et des structures de type diamant, ont été synthétisées au moyen d'un plasma d’argon en utilisant du méthane et du dioxyde de carbone comme précurseurs du carbone.De plus, des plasmas à couplage capacitif ont également été utilisés pour la fonctionnalisation du graphène et pour la synthèse de nanocomposites, tels que les composites de Polyaniline (PANI)-graphène. Les utilisations potentielles de ces matériaux ont été étudiées et les deux structures ont démontré avoir des attributs remarquables pour leur application aux biocapteurs. / Plasma environments constitute powerful tools in materials science by allowing the creation of innovative materials and the enhancement of long existing materials that would not otherwise be achievable. The remarkable plasma potential derives from its ability to simultaneously provide dense fluxes of charged particles, chemically active molecules, radicals, heat and photons which may strongly influence the assembly pathways across different temporal and space scales, including the atomic one.In this thesis, microwave plasma-based methods have been applied to the synthesis of advanced carbon nanomaterials including graphene, nitrogen-doped graphene (N-graphene) and diamond-like structures. To this end, the focus was placed on the optimization of the production processes of two-dimensional (2D) carbon nanostructures, such as graphene and N-graphene, by further elaboration and refinement of the microwave plasma-based method developed at the Plasma Engineering Laboratory (PEL). The scaling up of the synthesis process for high-quality graphene using surface-wave plasmas operating at atmospheric pressure and argon-ethanol mixtures was successfully achieved. Moreover, N-graphene was synthetized via a single-step process, by adding nitrogen to the argon-ethanol mixture, and via two-step process, by submitting previously synthetized graphene to the remote region of a low-pressure argon-nitrogen plasma. Nitrogen atoms were usefully incorporated into the hexagonal graphene lattice, mainly as pyrrolic, pyridinic and quaternary bonds. A doping level of 25% was attained.Different types of carbon nanostructures, including graphene and diamond-like nanostructures, were also produced by using methane and carbon dioxide as carbon precursors in an argon plasma.Additionally, capacitively-coupled radio-frequency plasmas have been employed in the functionalization of graphene and in the synthesis of Polyaniline (PANI)-graphene composites. The potential uses of these materials were studied, with both showing favourable characteristics for their applicability in biosensing applications.

Nanostructures de carbone

Plasma à basse température

Nanocomposites polymère-graphène

Structures de type diamant

Graphène

Free-standing carbon nanostructures

Low temperature plasma

Polymer-graphene nanocomposites

Diamond-like structures

Graphene

530.44

620.5

[pt] ABLAÇÃO POR LASER PULSADO DE ALVOS DE FERRO E NÍQUEL EM ÁGUA E SUAS IMPLICAÇÕES EM ASTROQUÍMICA / [en] PULSED LASER ABLATION OF IRON AND NICKEL TARGETS IN WATER AND ITS IMPLICATIONS IN ASTROCHEMISTRY

JOAO GABRIEL GIESBRECHT F PAIVA

02 December 2021

[pt] A pesquisa aponta para a possibilidade de realizar a reação de redução de CO2 (CO2RR) para a formação de nanomateriais de carbono por ablação a laser pulsado(PLA) de alvos magnéticos de Ferro(Fe) e Níquel(Ni) em água pura deionizada. Os materiais coloidais sintetizados foram caracterizados por diferentes técnicas de espectroscopias ópticas (UVVis, ICP-MS, FTIR e Raman) e microscopia eletrônica de transmissão (TEM), revelando a presença de nanopartículas de óxidos e hidróxidos de metais de transição, junto com nanomaterial orgânico. Esse último, é bem visível por TEM, espectroscopia de raio-X por dispersão em energia (EDS), espectroscopia por perda de energia de elétrons (EELS), e espectroscopia Raman, que indica a presença de carbono amorfo grafítico e vibrações CH. No caso do nanomaterial obtido do Níquel, os resultados FTIR confirmam a presença da fase do hidróxido beta-Ni(OH)2, enquanto as medidas Raman e TEM sugerem também a presença de nano-folhas de Ni(HCO3)2. Os resultados experimentais foram enfim discutidos no contexto da origem e da evolução de moléculas simples e complexas de interesse astroquímico, com foco especial nas espécies potencialmente formadas na superfície de pequenos corpos metálicos do Sistema Solar e grãos de poeira cósmica do meio interestelar. / [en] The proposed research points to the possibility to perform CO2 reduction reaction (CO2RR) to solid carbon nanomaterials by the pulsed laser ablation (PLA) of magnetic target of iron (Fe) and nickel (Ni) in pure deionized water. The synthesized colloidal dispersions were characterized by different optical spectroscopies (UV-Vis, ICP-MS, FTIR and Raman) and transmission electron microscopy (TEM), revealing the presence of nanosized transition metal oxide and hydroxide nanoparticles, together with organic nanomaterial. The latter is well visible by TEM, energy-dispersive X-Ray spectroscopy (EDS), electron energy-loss spectroscopy(EELS), and Raman spectroscopy, which indicates the presence of amorphous graphitic carbon and CH vibrations. In the case of Ni derived nanomaterial, FTIR results confirm the presence of a beta-Ni(OH)2 hydroxide phase, while Raman and TEM measurements suggest also the presence of Ni(HCO3)2 nanosheets. The experimental results were finally discussed in the frame of the origin and evolution of simple and complex molecules of astrochemical interest, with special focus on those species potentially formed on the surface of metallic minor bodies in the solar system and cosmic dust grains in the interstellar medium(ISM).

[pt] NANOPARTICULAS MAGNETICAS

[pt] INTEMPERISMO ESPACIAL

[pt] NANOESTRUTURAS DE CARBONO

[pt] ABLACAO POR LASER PULSADO

[en] MAGNETIC NANOPARTICLES

[en] SPACE WEATHERING

[en] CARBON NANOSTRUCTURES

[en] PULSED LASER ABLATION

Mechanisms of Formation and Thermal Stabililty of Functional Nanostructures

Anumol, E A

January 2012

There are many challenges in materializing the applications utilizing inorganic nanoparticles. The primary drawback is the degradation of properties due to aggregation and sintering either due to elevated temperatures or prevailing chemical/electrochemical conditions. In this thesis, various wet chemical synthesis methods are developed to obtain metal nanostructures with enhanced thermal stability. The thesis is organized as below: Chapter 1 presents the problems and challenges in materializing the application of nanomaterials associated with the thermal stability of nanomaterials. A review of the existing techniques to improve the thermal stability and the scope of the thesis are presented. Chapter 2 gives a summary of the various materials synthesized, the method adopted for the synthesis and the characterization techniques used in the material characterization. Chapter 3 presents a general template-less strategy for the synthesis of nanoporous alloy aggregates by controlled aggregation of nanoparticles in the solution phase with excellent control over morphology and composition as illustrated using PdPt and PtRu systems as examples. The Pt-based nanoporous clusters exhibit excellent activity for methanol oxidation with good long term stability and CO tolerance. Chapter 4 presents a detailed study on the thermal stability of spherical mesoporous aggregates consisting of nanoparticles. The thermal stability study leads to a general conclusion that nanoporous structures transform to hollow structures on heating to elevated temperatures before undergoing complete densification. Chapter 5 presents a simple and facile method for the synthesis of single crystalline intermetallic PtBi hollow nanoparticles. A mechanism is proposed for the formation of intermetallic PtBi hollow structures. The intermetallic PtBi hollow structures synthesised show excellent electrocatalytic activity for formic acid oxidation reaction. Chapter 6 presents a robust strategy for obtaining a high dispersion of ultrafine Pt and PtRu nanoparticles on graphene. The method involves the nucleation of a metal precursor phase on graphite oxide surfaces and subsequent reduction with a strong reducing agent. The electrocatalytic activity of the composites is investigated for methanol oxidation reaction. Chapter 7 presents a microwave-assisted synthesis method for selective heterogeneous nucleation of metal nanoparticles on oxide supports leading to the synthesis of high activity catalysts. The catalytic activity of the hybrids synthesized by this method for investigated for H2 combustion. Chapter 8 presents thermal stability studies carried out on nanostructures by in-situ heating in transmission electron microscope. The microstructural changes during the sintering process are observed in real time and the observations lead to the understanding of the mechanism of particle growth and sintering. At the end, the results of the investigations were summarized with conclusions drawn.

Nanomaterials

Metal-Carbon Nanostructures

Inorganic Nanoparticles

Metal Nanoparticles

Nanostructures

Nanoporous Alloy Aggregates

Nanoparticles

Hollow Nanoparticles

PtRu Nanoparticles

Graphene

Hollow Structures

Pt and PtRu Nanoparticles

Mesoporous Nanoparticle Aggregates

Porous and Hollow Nanostructres

Materials Science

Simulation der Nanostrukturbildung in Alkali-dotierten Fullerenschichten / Simulation of nanostructure formation in alkali-doped fullerene layers

Touzik, Andrei

07 March 2004

This work presents theoretical background for the investigation of nanostructure formation in alkali-metal doped fullerene layers. A number of computational methods are used to describe structural transformation in the fullerene layer. They include tight-binding molecular dynamics, empirical molecular dynamics, Monte-Carlo calculations as well as other methods. The doped fullerene layers show the highest superconducting critical temperature among organic superconductors. A new electrochemical method of synthesis of potassium and rubidium fullerides has been recently developed by Professor Dunsch and coworkers in the department of electrochemistry and conductive polymers at IFW Dresden. The process of electrochemical doping is accompanied by several side effects, and one of them is nanostructure formation at the surface of the fullerene layer. In the present work an explanation is given for the nanostructure formation observed recently by scanning tunnel microscopy. The corresponding model is based on the concept of spontaneous phase separation that has been realized by kinetic Monte Carlo calculations. These calculations predict instability of initially homogeneous alkali-doped fullerene layers. Due to the significant gap in the Madelung energy formation of an alkali-poor and an alkali-reach phase is expected. The results of the Monte Carlo simulations point out that the particle size of the corresponding phases remains in the nanometer range. Interpretation of experimental data for metal deposition on fullerene substrates can be easily given in the framework of the phase separation concept as well. Metal clusters of the size order 50 to 100 nm emerge in course of electrochemical copper deposition on alkali-doped fullerene layers. The electrically conductive paths through the insulating fullerene layer are probably responsible for the inhomogeneous copper deposition under electrochemical conditions. A novel computer program has been developed in course of this work, which is designed as a distributed application. It can be used for diverse conventional and kinetic Monte Carlo calculations. / Die vorliegende Arbeit präsentiert theoretische Arbeiten, die das Ziel haben, die Nanostrukturbildung in dotierten Fullerenschichten zu verstehen. Diverse Rechenmethoden wurden verwendet, um die strukturellen Umwandlungen in der Fullerenschicht zu beschreiben. Die Tight-Binding-Molekulardynamik, die empirische Molekulardynamik und Monte-Carlo-Berechnungen sowie andere Methoden sind eingeschlossen. Die dotierten Fullerenschichten zeigen die höchste supraleitende kritische Temperatur unter den organischen Supraleitern. Eine neue elektrochemische Methode der Synthese von Kalium- und Rubidium-Fulleriden wurde vor kurzem von Professor Dunsch und Mitarbeitern in der Abteilung Elektrochemie und leitfähigen Polymere am IFW Dresden entwickelt. Der Prozess der elektrochemischen Dotierung wird von mehreren Nebenprozessen begleitet, und einer davon ist die Nanostrukturbildung an der Oberfäche der Fullerenschicht. In der vorliegenden Arbeit wird eine Erklärung für die Herausbildung der Nanostrukturen, die mit Hilfe von Rastertunnelmikroskopie beobachtet wurden, gegeben. Das entsprechende Modell basiert auf dem Konzept der spontanen Phasenentmischung und wird durch kinetische Monte-Carlo-Simulationen realisiert. Diese Simulationen sagen Instabilität der zunächst homogenen Alkali-dotierten Fullerenschichten voraus. Wegen des wesentlichen Unterschieds in der Madelungenergie ist die Herausbildung einer Alkalimetall-armen und einer Alkalimetall-reichen Phase zu erwarten. Die Ergebnisse der Monte-Carlo-Simulationen weisen darauf hin, dass die Teilchengröße der entsprechenden Phasen im Nanometer-Bereich bleibt. Im Rahmen des Phasenentmischungskonzepts können auch experimentelle Daten zur Metallabscheidung auf Fullerensubstraten problemlos interpretiert werden. Bei elektrochemischer Kupferabscheidung auf Alkali-dotierten Fullerenschichten entstehen Metallcluster der Größenordnung von 50 bis 100 nm. Die elektrisch leitfähige Pfade, die in einer isolierenden Matrix auftreten, sind wahrscheinlich für die ungleichmäßige Kupferabscheidung unter elektrochemischen Bedingungen verantwortlich. Ein neuartiges Computerprogramm wurde im Rahmen dieser Arbeit entwickelt, das als eine verteilte Anwendung entworfen ist. Damit können diverse konventionelle und kinetische Monte-Carlo-Simulationen durchgeführt werden.

Alkalimetall-Fulleriden

C60

Fullerenen

Kalium-Fullerid

Kohlenstoff-Nanostrukturen

Molekulardynamik

Monte-Carlo

Phasenentmischung

Rubidium-Fullerid

kinetische Monte-Carlo-Simulationen

C60

Carbon nanostructures

Monte-Carlo

alkali-metall fullerides

fullerens

kinetic Monte-Carlo

molecular dynamics

phase separation

potassium fulleride

rubidium fulleride

ddc:530

rvk:UP 7700

Fullerene

Fulleride

Molekulardynamik

Monte-Carlo-Simulation

Nanostruktur

Simulation der Nanostrukturbildung in Alkali-dotierten Fullerenschichten

Touzik, Andrei

17 March 2004

This work presents theoretical background for the investigation of nanostructure formation in alkali-metal doped fullerene layers. A number of computational methods are used to describe structural transformation in the fullerene layer. They include tight-binding molecular dynamics, empirical molecular dynamics, Monte-Carlo calculations as well as other methods. The doped fullerene layers show the highest superconducting critical temperature among organic superconductors. A new electrochemical method of synthesis of potassium and rubidium fullerides has been recently developed by Professor Dunsch and coworkers in the department of electrochemistry and conductive polymers at IFW Dresden. The process of electrochemical doping is accompanied by several side effects, and one of them is nanostructure formation at the surface of the fullerene layer. In the present work an explanation is given for the nanostructure formation observed recently by scanning tunnel microscopy. The corresponding model is based on the concept of spontaneous phase separation that has been realized by kinetic Monte Carlo calculations. These calculations predict instability of initially homogeneous alkali-doped fullerene layers. Due to the significant gap in the Madelung energy formation of an alkali-poor and an alkali-reach phase is expected. The results of the Monte Carlo simulations point out that the particle size of the corresponding phases remains in the nanometer range. Interpretation of experimental data for metal deposition on fullerene substrates can be easily given in the framework of the phase separation concept as well. Metal clusters of the size order 50 to 100 nm emerge in course of electrochemical copper deposition on alkali-doped fullerene layers. The electrically conductive paths through the insulating fullerene layer are probably responsible for the inhomogeneous copper deposition under electrochemical conditions. A novel computer program has been developed in course of this work, which is designed as a distributed application. It can be used for diverse conventional and kinetic Monte Carlo calculations. / Die vorliegende Arbeit präsentiert theoretische Arbeiten, die das Ziel haben, die Nanostrukturbildung in dotierten Fullerenschichten zu verstehen. Diverse Rechenmethoden wurden verwendet, um die strukturellen Umwandlungen in der Fullerenschicht zu beschreiben. Die Tight-Binding-Molekulardynamik, die empirische Molekulardynamik und Monte-Carlo-Berechnungen sowie andere Methoden sind eingeschlossen. Die dotierten Fullerenschichten zeigen die höchste supraleitende kritische Temperatur unter den organischen Supraleitern. Eine neue elektrochemische Methode der Synthese von Kalium- und Rubidium-Fulleriden wurde vor kurzem von Professor Dunsch und Mitarbeitern in der Abteilung Elektrochemie und leitfähigen Polymere am IFW Dresden entwickelt. Der Prozess der elektrochemischen Dotierung wird von mehreren Nebenprozessen begleitet, und einer davon ist die Nanostrukturbildung an der Oberfäche der Fullerenschicht. In der vorliegenden Arbeit wird eine Erklärung für die Herausbildung der Nanostrukturen, die mit Hilfe von Rastertunnelmikroskopie beobachtet wurden, gegeben. Das entsprechende Modell basiert auf dem Konzept der spontanen Phasenentmischung und wird durch kinetische Monte-Carlo-Simulationen realisiert. Diese Simulationen sagen Instabilität der zunächst homogenen Alkali-dotierten Fullerenschichten voraus. Wegen des wesentlichen Unterschieds in der Madelungenergie ist die Herausbildung einer Alkalimetall-armen und einer Alkalimetall-reichen Phase zu erwarten. Die Ergebnisse der Monte-Carlo-Simulationen weisen darauf hin, dass die Teilchengröße der entsprechenden Phasen im Nanometer-Bereich bleibt. Im Rahmen des Phasenentmischungskonzepts können auch experimentelle Daten zur Metallabscheidung auf Fullerensubstraten problemlos interpretiert werden. Bei elektrochemischer Kupferabscheidung auf Alkali-dotierten Fullerenschichten entstehen Metallcluster der Größenordnung von 50 bis 100 nm. Die elektrisch leitfähige Pfade, die in einer isolierenden Matrix auftreten, sind wahrscheinlich für die ungleichmäßige Kupferabscheidung unter elektrochemischen Bedingungen verantwortlich. Ein neuartiges Computerprogramm wurde im Rahmen dieser Arbeit entwickelt, das als eine verteilte Anwendung entworfen ist. Damit können diverse konventionelle und kinetische Monte-Carlo-Simulationen durchgeführt werden.

info:eu-repo/classification/ddc/530

ddc:530